Electrical insect killer with fire preventing means



Dec. 8, 1953 E, KRETscHMAR ELECTRICAL INSECT KILLER WITH FIRE PREVENTING MEANS Filed yJuly 7, 195o 2 Sheets-Sheet l Dec. 8, 1953 E. KRETscHMAR 2,661,512

ELECTRICAL INSECT KILLER WITH FIRE PREVENTING MEANS Filed July v, 195o 2 sheets-sheet 2 MSI) vmQ

.ux #i Nub EST l @Trop/VE #s Patented Dec. 8, 1953 UNITED sTArs ,PATENT OFFICE ELECTRICAL INSECT KILLER lil/'1THFIREV PREVEN'ING` MEANS 'Ernest Kretschmar, Clayton, Mo.

Application July 7, 1950, Serial No. 172,567

suchas that shown in Stone `Patent No. 2,373,428,

of April l0, 1945. It will of course be understood that-it isadapted for use in. many other con- .nections' inwhich it `is Adesirable or necessary to maintain a particular ratio or relative density betweenrcomponents 4of the atmosphere within an-enclosure. 'Y But Vin connection with electrical devicesv of the type mentioned, there is a nre hazard ifnormalatmosphere is present surroundingthe electrostatic device, since sparks may occuriand could cause explosion; so that Vthe presentapparatushas especial value in automatica-ily regulatingthe--ratio of an inert component of the `atmosphere -in an insect killer.

In `the particular .device-referred to, there is a grid consisting of, alarge number of spaced conductors, across which grain or the like may be Acaused to1ow. Thegrain is non-conductive, but any insects or similar Iliving matter that shortcircuit between yadjacent and 'oppositely charged grid elements will conduct. electricity, and the current is such as to electrocute the insects.

Preferably, such insect; killing apparatus Iis `used in' a `constantly moving grain stream. In the present invention, the insect electrocutor is illustra-ted:asi having grids and having .a `divider motor, which is a convent-Qual piece of appa- :a:

ratus designed -to- -feedaA properlyeven'streain of grain to the grids. Thefdividermotor, whenopaerating.-y feeds; .the ngrain thus properly `to one end of Vthe gridor the grids. These gridsfmay be arranged so that;theyslopedownwardly, with the i result that thexgrain descends by gravity from the upper ends `of the `grids to the lower ends, during which insect electrocution may take place.

Whilein theeleetrocuting device oi the Stone "Patent thel insects werev electrocuted, itwas dis covered that there could be some rire hazard `because oiithepresence .of grain vdust and the like ina normal atmosphere within the. confined space ci the housing fofntheyequipment. YThe present invention iszrdesigned to eliminate the' yiire hazard :providing .an atmosphere 4sufficiently heavy in an 'inert gas component such as ,carbonnioxide,

yto vrender the connedatrnosphere inert to such sparking.

The presentV inventionv notonly maintains the V atmosphere inert by the delivery of carbon dioxideintofthe :housing of` the eleotrocuting apfparatus,but it alsozmaintains `that atmosphere `within ,.afsafely inert-range automatically. In

addi-tion; if torfanyunexpected reasonthe atmos- ,grid `device l 5.

(Cl. .2l-102) 'phere shoulddrop to a'dangerous range oLcarbon dioxide, thegpresent apparatus automatically deenergizes the electrostatic grids vso that no explosion can take` place.

Furthermore, the present Yinvention has indicators thereon that will indicate its various conditions. `Thus, when the carbon dioxideis being autonriaticallt7 supplied to the housing, a suitable visual Vindication thereof will be given. when the principal supply of `carbon doxideis cut often indication thereof ,will result. 1f4 the dangerous condition otatmosphere exists within `the apparatus, this will be indicated .by another signal.

Aclditionally, the equipment ,is completely ,deenergized when thecontrol mechanism is entirely Ashut off, as `byrnanual action.

Another feature of the presentinventionis that there will 4always be .acertain minimum `supply of. kcarbon dioxide to the chamber, .accompanied ,by anintermittent .supply of a larger volume of carbon doxide thereto as needed. This results in amore even Vmodulation of the atmosphere Within the electrocuting chamber, and also a more economical operating cycle.

Thereis .pressure regulation of the 4carbon dioxide delivered to the electrocuting chamber, and inaddition the control includes temperature regula-ting ineans that prevent freezing adjacent to the pressure regulating devices.

.Other features 1of the invention will appear from ,the description to follow.

In the drawings:

. Figure lY is -asomewhat diagrammaticxyiew of ,the instrumenten-ties:involved in the present ap- .paratuS-.tand

Figure 2 isa wiring diagram of theapparatus. It is thoughtfunnecessary to describe the elec- ,trocuting apparatus in detail Sincev the Stone patent illustrates an embodiment thereof. fn Eig/ure l,it -is.shown-generaliy'at le, therebeing ya-'housing liV therefor. There is a grain feeding .means l Zgat` the tcp-.of the housing. i I; thefeedingofA grain ,into which is regulated by a divider .motor :13.

AlfVithi-n the-housing, there is any electrostatic One ori more of i thesemay be used. .tffisfarranged on a `slope and it consists v.oi- -a-.plurality of uelectrically separatedi-and ialternately charged conductor elements, as nadivagrarnined Figure 2. These. grid elements are spaced together adistance suitable to produce conduction between adjacentgrid elementsovhenl ever an insect .ofthe type normally found in the grain orotherlmaterial .being treated is presented as between adjacent grids. After leaving the sloping grids l5, the grain descends into other processing elements of the grain treating system. The grid is charged a suitably high potential from a grid transformer i6.

The present invention operates to maintain an atmosphere within the housing H that is inert so that explosion cannot take place therein should sparks occur from the grid action. For example, a safe atmosphere can be one that is above 34% CO2. Consequently the present control apparatus may be set to assure a density of 34% CO2 at all .times when the grids are energized, and to deenergise the grids should the CO2 density drop below 34%. Furthermore, the control acts to prevent the wastage of carbon dioxide by limiting the maximum density thereof. This consists of a control apparatus that will shut off a main CO2 valve when the density within the housing Il reaches a value somewhat higher than 34%, such as 35%. This main supply of carbon dioxide is out on again should the density descend to 35%. Thus, in short, the equipment will prevent energization of the grid until the carbon dioxide density within the housing H is at a safe value such as 34%, and will thereafter maintain the density of carbon dioxide between 35% and 36%.

The control apparatus operates to regulate a gas supply means, regulating delivery of gas from a suitable source, which is here shown as two carbon dioxide cylinders 29 and 2i. These are both connected into a change-over valve 22, which is of the automatic type commercially available so that it automatically shifts from one cylinder to the other as the rst is emptied.

The change-over valve discharges into a line 23 that connects into a carbon dioxide heater 24. This heater is designed to heat the carbon dioxide prior to its entry into a pressure regulater, so that it will be above a temperature at which freezing may occur at the regulator.

The heater discharges into a pipe 25 that connects into a low pressure regulator 26. This pressure regulator has a suitable pressure gauge 2l, and is set to a proper pressure such as six to eight pounds, this having been found satisfactory. From .the pressure regulator 26, a carbon dioxide feed line 23 leads into a T 29. From this T, a main carbon dioxide feed line 3l) leads into a main solenoid valve 3l. From this main solenoid valve 3i, the carbon dioxide feed line continues at 32 to a T 33. From this T, the carbon dioxide feed line continues at 34 to a T 35, from which two branches 36 and 3l open into the top of the housing. It is preferable to admit the carbon dioxide at the upper part of the housing Il, as, being heavier than air, it will descend and thereby will produce a proper atmosphere throughout the housing l I.

There is a bypass around the main solenoid valve 3! in the carbon dioxide feed line. This bypass extends from the T v29 by a pipe 40 that connects into a bypass solenoid valve lll. From this bypass solenoid valve, the bypass line continues at i2 into a needle valve 33, and from this, by a pipe 44, back to the T 33. As will appear, the bypass solenoid valve is open whenever the apparatus is operable at all. By this arrangement, the needle valve 43 can provide a regulated minimum supply of carbon dioxide to the housing ll at all times, regardless of whether the main solenoid valve 3l is closed. The supply of a minimum amount of carbon dioxide to the housing means that the atmosphere will always be partially charged with carbon dioxide, and will preferably be charged with the maximum amount that can practically be used without overcharging under certain conditions of operation of the electrocuting apparatus lil. By this means, the main solenoid valve can operate intermittently and is required to modulate the density of carbon dioxide only within a relatively narrow range.

The foregoing parts of the apparatus are under an automatic control that is based upon a carbon dioxide analyzer, and which includes certain other switches. This control is shown in its principal elements as mounted on a single panel 53 shown in dashed lines at the middle part of Figure l. On this panel, there is mounted a carbon dioxide analyzer, generally indicated at 5 l. In addition, there are four control switches 52, 53, 54 and 55 arranged on the panel. While the details of these switches will be considered more hereafter, it may be mentioned at this time that the switches 52, 53 and 55 are manual switches, such as double-pole, single-throw switches, whereas the switch 5i! is a compound relay switch.

Also on the panel, there is a carbon dioxide and grid relay control device 55, and there isa carbon dioxide indicator 5l.

A sampling tube 69 extends into the housing El of the electrccuting device I0. It connects into a small blower or fan device Si, by which gas is drawn through the tube 6i? and delivered into 4the carbon dioxide analyzer 5I. The blower 6I is electrically operated, and a reference to Figure 2 will show that it discharges the atmosphere into a head t3 on the analyzer. This head is above a porous resistance plate 565, and below the latter there is a container E5 that constitutes a carbon dioxide absorption tank lled, for example, with potassium hydroxide.

The head 63 of the analyzer 65 has an atmosphere vent 55, It also has a pipe 6l' that leads into a diaphragm chamber 68 that is closed by a diaphragm ES. This diaphragm actuates a bell crank switch control lever 'iii that is pivoted at H on a suitable mount. A spring l2, with a tension adjuster '53, normally draws the lever 'I9 in such direction as to lift the diaphragm B9. The outer end of the lever lil has two magnets 'ld and 15 thereon.

Adjacent the head of the lever lil are two stationary mercury switches T'l and 18. Each oi these tubes contains a portion of mercury in a suitable well at its bottom. Each also has a fixed conductor leading down into the mercury. Thus the switch 'il has a fixed conductor TS and the switch 18 has a fixed conductor EB. Each switch also has a magnetically responsive movable switch lever. The switch 'll has such a ezver 8i, whereas the switch 78 has such a blade When the switch operating lever 10 is toward the switch 18, as illustrated in Figure 2, the magnetically responsive blade 82 will be pulled out of the mercury so that the switch is opened. However, the blade 8l of the switch 11 will be released so that its end enters the mercury and closes circuit with the fixed switch element 1Q. When the switch arm 10 is in neutral position between the two switches 'l1 and 18, they both will be closed.

In this type of analyzer, increase in density of carbon dioxide within the housing l l (and hence in the analyzer 5 I) results in an increase in pres- Sure in the line 67, and hence in the diaphragm fegeersra wchamber ."d. i When ythis operating `frpressure iis below afw mi!iinfiurn` value; the switch. lever' 'l 0 1 will remain in 'its full line positioniadjacent thefswitch TF, holding the same ropen, fand permitting .the

'switchl to close. :As'theldensity .off carbon ldioxide increasesV above'this minimum, the fdiaphragm will rise, and .move thetswitch.memberfy le to neutral position, wherein .both switches ''l and le areclosed. As thedensity reaches arnaximum, the member le moves .to .the `fdashed. line position of Figure 2, wherein itopensttheirswitch 78, the switchl'l remaining closed.

Thereafter, as the density of ,carbon'dioxidetdescenda the lever 'it will 'be Inovedzaway irornzthe switch 'it .to'a neutral :position:perrnitting the switch 'lilto olosewhile/the switchil'freniains closed. .if the density.oicarbonsdioizide descends further to a certain minimum, .theizbladelrwill move to' the letin `Figure 2Y untilfthenia'gnet "M opens the switch Tl again.

The relay 5ft previouslyxmentioned .isgmounted uponfthepanel 5i?. Itincludes. a coiliandna three-way switch arrangement SL @E .sanded i It will be seen that, when the coiled is deenergize'd, the switch 9E closed, whereas thezswitches'il and 93 are opened. Whenthe coiled is :ener- -igized, .the switch'fei 4is opened,xbut1 the switches 92 anidft are. closed.

.The panel 4boardalso includes twoV signals, here shown as agreenlight-tlanda red lighrl.

'The `wiring .of theiorego'ing 'includeszal ller-volt Vor low'` voltageinetworlr". and la .220'-volt or 1 high voltage network.

The high voltage network includes two high voltage lines ist :and` l@ l. the switch SELand the line lili leads .to the-switch 93. The other sides ci' the two respectivelsvvitches areconnected by lines le? and it. to .the grid transformer le, from which ltheoutlet lines .lead oppositely to the elements'of the; grid l5.

rihe switch 5? and .divider .motor .Stare connectedacrosg the high voltage' 4lines it@ and 'lil I. Thus, branches 'i eiland m5 `lead to the switchl53.

'..and the divider motor I3 isconnectedtothe outlet sides of thisswitch 53h51 lines 'liluand itl.

The low Voltage network includes two 11G-volt lines, llilandlli. The line il@ leadsidirectly to one side of the manualswitch 52,`and.the `line Hi leads totheother sidethereof. .The outlet Yiside of the. switch 52 is .connected :byi lines H2 .and i lto theoppositeends of thecarbonzdioxide heater 2li.

. Additionally, there are branch lines I'l l and i Il connected to the 11G-volt leads llrand' El 1,1 respectively, that lead to the switch 55 which .isV the isa return lead. eonnectinginto .the wire :l 9..

The branch wire i2@ also-.hasaconnection- .[26 that leads to the relay. switch 9 l.. Fromthe other side oi"Y this switch, afwire l2? extends 4tothe. red light 9i and thence to the return lead 125.

The wire i2! connects .intothe flxedfterminal et of the switch ld. The other movable terminal 82 of the switch is is connectedby a wire lzuthat leads, in parallel, to the main carbon dioxide Asolei noid valve 3! and to the green'light 96,' and. thence into the return wire |25.

The branchA .zromthe switchlead :H8 con-` The. :li-ne ite. leads' to the --.switch 55 .isfclosed .closeda circuit is closed from the. llthvolt lines nectsfdown and: branchesfat 1.30 :and l3l. The .branch l301leads throughthecoil of thexcarbcn dioxide bypassvsolenoid il l, from .which a wire' 132 connects toa wiref `l33that leads to the wirey l l, and backthroughxthe switch. The `branch l3i -ofthevwiref 1.122y leads through .the electric motor of; the fanzor'blower L'from which another wire |34 leads back. tothe wire1l33 and' thence to the `switch-155.

"Operation Atthestartof anyoperation of the electrocuting apparatus fihi-,here will be grain. up tothe Tdividerll 2. The connections will be made as have .been indicated. 'A supplyhf carbon. dioxide will '.beattaehed .to the change-over valve. The pressure regulatorlawillbe setfforthe'desired pressure. "he: needle valve.' G3 will beset to maintain the.` maximum amount of carbon dioxide `in the; carbonldioxide feed line that cannot overload: thehousing ll. AThe carbon dioxide relay control will' have its adjustment 'i3 set to determine its operatingpressures that will maintain .the .desired density .of carbon dioxide within .the housing." l. The several switches will be in the i positions shown, all the manual switches. 52, 53

andi being open, the relayi being deenergized to the position illustrated. .As the density of carbon`dioXiole at a startis very low, the diaphragm. S9 will-be low and the switch arm 'lll will be asv shown. in' 'full' lines, in which position its magnet "llt attracts the blade. 8l to open the switch" Tl. lVIeanWhileLthebladeSZ .being released, the switch I8 willbe closed.

.Aninspecticn .of the. wiring. diagram will show .that-.all of theoperating mechanisms are deenergized .andthe apparatus is at rest. As both solen .noidfvalves 3| .andAta-re. clcseclthe carbon dioxide supplyis entirely. out oiyso that the valves .1 .onthetanks 2t. and 2 l. maybe left open, particum larly if the machine is not to be left inoperative for .1one,.-Derio.ds.

Tofstart the machine, the-switch 521s closed, thisfenergizingthe. carbondioxide. heater. Then When theswitch 551s :through .this switch to energize the lines E Iand i lily. .the-latter` being for purposes Vof Vdescription considerediaswthefretitrnzline. V.As soon as .the

switch :555isf.closed,1therefore, a circuit is corn niitscarbon-.dicxicle toiiow fronrone .of the cylin- .itclersatliand-. l`vr through' .the change-over valve 22,

thepipe throughitheiheater Ztl, thence by way .otheffpipeei the low pressure regulator 26 into :n.thareediine 2S. Thezmain solenoid. 3l is at this 'time fclosed, ibut. the i bypass' connection extends --throiighfthexpipe dil, the now open bypasssole- `incid-valve Lithepipe the properly adjusted :needle valVeJlS, thepi-pe lit, the pipe l5 and the ztnpiipes .and'l .intothe top of the housing Il. .Atiithe same time, 'the blower draws samples of atmosphere through the sampling tube 6i) and discharges thesameinto the-head'of the COz'analyzer. Asethecarbondioxide content is-relatively low in this atmosphere, the carbon dioxide will be substantially all absorbed in the potassium hydroxide in the tank S5, and substantially no pressure will build up at the outset in the head and in the pipe 61 leading to the diaphragm chamber 63. Hence the diaphragm 59 will be in a lower position, and the switch arm 'I3 will be in the position indicated in full lines in Figure 2.

The closure oi the switch 55 also energizes a circuit through the branch line IZI that extends upwardly through the now closed switch 'I8 and out therefrom through the line E28 to the coil of the main carbon dioxide solenoid valve 3l, the green light 95, and back to the return lines |25 and IIS. Consequently, when the switch 55 is closed, the green light will burn and the main solenoid valve 3l will open. This will cause a substantial discharge of carbon dioxide through the carbon dioxide feed line and into the top of the housing I I. The fact that the main carbon dioxide valve 3l is open is thus indicated by the presence o the green light.

At this time, the branch I2i), leading from the switch 55, is energized because the relay switch SI is closed (its coil being deenergized). This branch extends from the switch d! through the red light el and back by return lines 25 and I I9, thus causing the red light to burn, indicating an unsafe atmosphere in the housing I I.

As the density of carbon dioxide within the housing I I increases, this will be indicated by the analyzer 5|. It will be reflected in a gradual increase in pressure within the diaphragm chamber 68, and hence a lifting of the diaphragm 69.

This will be followed by a shifting of the switch and the switches $32 and 93 are closed. When the l' switch SI opens, the red light 9i is put out of circuit, thus indicating that atmosphere within the housing il is safe with respect to CO2 content. When the switches S2 and 93 close, the 22B-volt power lines ISG and I5! are connected to the transformer I 5 that energizes the grids I 5. Consequently, these grids I5 are energized only as soon as the atmosphere is safe from explosion.

As soon as the extinguishment of the red light indicates a safe atmosphere in the housing I I, the l switch 53 may be closedy to start the divider motor I3, which then causes a feed of grain to the grid.

Under the circumstances thus far described,

the density of carbon dioxide is at least at the saie minimum, here suggested as 34%. The particular density at which the switch arm IG shifts to neutral is predetermined by the setting of the regulator 73. With the arm lIi in neutral, the main carbon dioxide valve 3! continues open. However, as the density of carbon dioxide builds up, accompanied by a further increase in pressure in the diaphragm chamber S8, it will reach a certain maximum value for this control. When this maximum Value is obtained, the control arm 'ID is thrown over to the dashed line position, where its magnet I5 attracts the blade 82 of the switch 18, thereby opening that switch. lThis immediately deenergizes the green light SS and the main carbon dioxide valve 3l, which latter closes. Thereatmosphere.

after the supply of carbon dioxide is only that admitted through the bypass solenoid Valve,

Should the density of carbon dioxide within the housing I I drop when the main solenoid valve is closed oil'. as it will normally do in due course of time, the pressure within the diaphragm chamber will decrease, and the arm 'It will move back to its neutral position, wherein both of the switches 'Il and 'I8 are closed. When it does so, it

releases the switch 'I8 to reclosed position, causing the main carbon dioxide valve to reopen and the green light to burn. Such condition may exist when the density of carbon dioxide descends from the 36% maximum to an intermediate Value such as 35%. There is, of course, an inherent diier ential. in switches of the type illustrated at but this differential may be controlled by a suitable known means.

Thus, in normal operation at the start of the apparatus, the grids will not be energized until the carbon dioxide density attains a safe degree such as 34%. Thereafter, the grids will be energized, and the carbon. dioxide content will continue to rise a slight amount that provides an operating range for the equipment. When the carbon dioxide content reaches a maxin'ium value, the `rate of inilow of carbon dioxide will be reduced to that provided through the bypass line, which is below that required to maintain the safe Thereafter, the apparatus will cause the charging of carbon dioxide lto cycle within a small range, which range is above the minimum required for safety.

If at any time for any reason the density oi carbon dioxide should drop below the safe density within the housing I I, the diaphragm ES will fall and the switch blade i0 will move over to the switch TI, reopening the same, lighting the red lamp il?, and deenergizing the grid transformer I@ so that the grids I5 are deenergized and no sparking can possibly occur. The grids l5 will remain deenergiz-ed until the carbon dioxide content builds up again. The operator is warned by the presence of red light so that he may stop the divider motor by opening the switch t-Zi as necessary.

While this apparatus has been described in connection with the maintenance of proper density oi carbon dioxide within a housing of an elec-- trocuting device for insects, it will be understood that the control is capable of further and broader uses where it is necessary to maintain a density of gas automatically in some enclosure. Also, other individual features of the invention are capable of other uses as will be apparent. However, there is the particular objective ci' the inu vention to provide safety equipment of automatic characteristics for use in electrical machinery, and most particularly in. an electrical insect killer of the type illustrated in the Stone patent.

What is claimed is:

l. In a machine for treating material in a housing with an electrical current, and for maintaining a non-explosive atmosphere in the housing: the combination of a housing as aforesaid; electrical means in the housing to receive and treat the material; feeding means to feed the material to the electrical means; intermittent gas supply means to supply a component of carbon dioxide gas to the housing to render the atmosphere therein non-explosive; a gas analyzer operable to indicate the density of said component in the housing; the analyzer being adapted to pro duce a pressure that varies with the density of the gas component in said atmosphere; a pressureeresponsive; switch-mechanism -havlngg afrst switch device; an second; switch,` device;` and a member movedY by pressurezzchanges .produced/by increasing density :of the gas .from .ai p-osition'to the first switch device,..to.;a neutral position; and thence to a position to open the second switch device, both. switch devices being adaptedfto close when not so operated;. a contr-cl device; for rendering the electrical meansv operative, said control being connected with the iirst switchde vice, whereby said control devioecan'cause opera, tion of the electrical means only when the density attains a value to -move the switch-operating member to neutral position; the gas supply means` beingV connected-.i with the second switch device, whereby, it will be` renderedinoperative only when the density attains a value to move the Switchs-operating member beyond neutral, to posi tion for opening-the second'switchoperating vice, and will ibetrendercd"'operative ag,I when density :falls to' return-the switchoperatingl meinber to neutral.

2. In a machineY iorAtr-eatingi, inaterialgin a housing with en el t cai current, and for maintaining non-expl e o 1ere in the housing: the combination oi' a housing as aforesaid; electrical meansiin the housing toreceive-and treat thematerial; feeding/means toieed .the material to th'eelectrical means; intermittentga-s supply means to supply-a component gas-to the housing to render the atmosphere therein nomexplosive; a gas analyzer operable to indicate the density of said component in the house ing; the analyzer being adapted to produce a pressure that varies with the density of the gas component in said atmosphere; a pressure-responsive switch mechanism having a first switch device, a sec-ond switch device, and a member moved by pressure changes produced by increasing density oi' the gas from a position to the first switch device, to a neutral position, and thence to a position to open the second switch device, both switch devices being adapted to close when not so operated; a control device, for rendering the electrical means operative, said control being connected with the first switch device, whereby said control device can cause operation of the electrical means only when the density attains a value t-o move the switch-operating member to neutral position; the gas supply means being connected with the second switch device, whereby it will be rendered inoperative only when the density attains a value to move the switch-operating member beyond neutral, to position for opening the second switch-operating device, and will be rendered operative again when density falls to return the switch-operating member to neutral, and means to supply said gas component in predetermined constant amount to the housing.

3. An apparatus for electrocuting insects and the like in a stream of moving particles such as grain, and for providing a non-explosive atmosphere in the housing: a housing as aforesaid, electrical grid means in the housing, means to cause the stream of material to flow over the grid means; an inert gas supply means connected into the housing, a gas analyzer to determine the density of said inert gas in the housing and to operate a movable element as a function of variation in such density; a first control switch and a second control switch spaced from the rst, said switches being normally closed, the movable element being adapted to open said switches when adjacent to them, and being 1novable, as density increases, from adjacent the iirst 10 Switchs-.to ncutralito adjacent the Secondv Switch; srdzienersizatio... .means .connected throughthe first switchto prod cY grid energization only when thehrst switc4` `lsfllosed and hence-only when increasing gas density has moved the pher A, the houin gf L -.housingfaa aforesaid,- electrical g1T means..-in= thehousing,meanspto @aus he. Si, met 1.ateria1tQ-cv0ver-the arid d Sunclr means. Connected; nalyzer to determine the de thahcusinssandato asafunction. if-varia:- tionr dosi-lob; density; a i. Erst control Switch;- andasecondwontl Sivitchepavedwm; the @ist Said Switchesb..msgliormallv Closed, the movable: @inheritY bena adantedto; Open Said Switches adiacentto; there; .and f beine f in:.vablavv as. densitv-zi11c1eases;from adiaent ,the'rst Switc tof.neutral.; ,to adiacentthe` Second switch; and, enersizaticnr-means:connected; tbl-.Gush the switch: produce. arid; energaati-er1,` only the fuis... switch.:y 1S: Closed fand; hence; only.: i een increasing gas density has moved the switch element as far as neutral position; and the gas supply means being connected through the second control switch, whereby to deliver gas except when the switch element is beyond neutral position, and indicating means operated through each of said control switches.

5. The combination of claim 3, with main control means operable to control all of the aforesaid mechanism; and with an additional supply means to supply a constant amount of inert gas to the housing, rendered operative upon operation of the main control means.

6. The combination of claim 5, wherein there is a pressure regulator for the inert gas, and there is a heater therefor that is rendered operative upon operation of the main control means, and said inert gas is carbon dioxide.

7. The combination of claim 5, wherein the gas analyzer has a gas iiow means to deliver gas from the housing, which gas ow means is connected to be energized upon operation of the main control means.

8. In apparatus for delivering a gas into a housing: aotuable means in the housing; a gas supply line leading into the housing; a valve in said line; electric means for opening and closing the valve; a gas analyzer connected into the casing and having means movable responsively to the amount of the gas in the atmosphere within the casing, the movable means being movable from iirst to second operating positions and also being disposable between those positions; the analyzer disposing the movable means in iirst position when the gas content is as great as a predetermined amount, in second position when the gas content is as low as a lower predetermined amount, and in mid position between the iirst and second positions when the gas content is between said predetermined amounts; rst switch means operated by the movable means in rst position to operate the electrical means to close the valve, second switch means operated by the movable means in second position to render the actuable means inoperative, the movabie means in its mid position rendering the first switch operable to operate the electrical means to open the valve, and rendering the second switch operable to eiect actuation of the actuatable means.

9. In a control for regulating delivery of carbon dioxide combustion suppressing gas to a casing: electrically operable apparatus in the casing; a conduit for delivering the gas to the casing; a sampling device, an electrically operated blower for discharging atmosphere from the casing through the sampling device; a relay having a coil and a switch, the switch being in circuit with the electrically operatable apparatus; an electrically operatable valve in the conduit; a rst switch in circuit with the valve, a second switch in circuit with the relay coil; the sampling device including a member movable to position to open the first switch and to second position to open the ysecond switch and to neutral wherein both switches are closed, and the sampling device also including operating means to move the member to rst position when the amount of carbon dioxide gas in the casing is up to a predetermined amount, and then to second position as the amount of the carbon dioxide gas descends to a predetermined lower amount; and a main switch operable to start the blower, to put the first and second switches in circuit along with the valve and the relay coil, so that the ERNEST KRETSCHMAR.

References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,638,104 Roucka Aug. 9, 1927 2,296,747 Stover Sept. 22, 1942 2,299,109 Rand Oct. 20, 1942 2,373,428 Stone Apr. 10, 1945 2,467,181 Barnard et al Apr. l2, 1949 2,470,043 Monsarrat May 10, 1949 OTHER REFERENCES Gas Analysis and Testing of Gaseous Materials, by V. J. Altieri (1945), published by American Gas Association Inc., 420 Lexington Ave., New York, New York, pages 127 to 137. 

